Failed remyelination of the nonhuman primate optic nerve leads to axon degeneration,retinal damages,and visual dysfunction

White matter disorders of the central nervous system (CNS), such as multiple sclerosis (MS), lead to failure of nerve conduction and long-lasting neurological disabilities affecting a variety of sensory and motor systems, including vision. While most disease-modifying therapies target the immune and inflammatory response, the promotion of remyelination has become a new therapeutic avenue to prevent neuronal degeneration and promote recovery. Most of these strategies have been developed in short-lived rodent models of demyelination, which spontaneously repair and do not reflect the size, organization, and biology of the human CNS. Thus, well-defined nonhuman primate models are required to efficiently advance therapeutic approaches for patients. Here, we followed the consequence of long-term toxin-induced demyelination of the macaque optic nerve on remyelination and axon preservation, as well as its impact on visual functions. Findings from oculomotor behavior, ophthalmic examination, electrophysiology, and retinal imaging indicate visual impairment involving the optic nerve and retina. These visual dysfunctions fully correlated at the anatomical level, with sustained optic nerve demyelination, axonal degeneration, and alterations of the inner retinal layers. This nonhuman primate model of chronic optic nerve demyelination associated with axonal degeneration and visual dysfunction, recapitulates several key features of MS lesions and should be instrumental in providing the missing link to translate emerging repair promyelinating/neuroprotective therapies to the clinic for myelin disorders, such as MS.

White matter disorders are a large group of neurological diseases of various origins. Those affecting the central nervous system (CNS), such as multiple sclerosis (MS), lead to failure of nerve conduction, axon degeneration, and result in long-lasting neurological disabilities and tissue atrophy (1). The loss of myelin and healthy axons are believed to be responsible for irreversible damages, which affect a variety of sensory and motor systems, including vision. In MS, 70% of patients are affected with optic neuritis. It can manifest in an acute episode with decreased vision that can recover over several weeks in the majority of patients, while permanent visual symptoms persist in 40 to 60% of patients (2, 3). Chronic optic neuritis can lead to significant optic nerve atrophy and retinal alterations, affecting mainly the retinal inner layers, including the retinal nerve fiber and ganglion cell layers (4). Several visual assays, including visual fields (VF) (5), pupillary responses to luminance and color (pupillary light reflex, PLR) (6), electroretinograms (ERG) (7), optical coherence tomography (OCT) (4, 8), and visual evoked potential (VEP) (9–11) are routinely performed to assess noninvasively the anatomical and electrophysiological perturbations of visual functions in MS. While functional recovery was reported in some patients (9), the lack of anatomical–electrophysiological correlation has prevented to attribute directly these improvements to remyelination or other regenerative processes.Animal models of demyelination induced by toxins, such as lyso-phosphatidylcholine (LPC), are suitable for studying the mechanisms of demyelination/remyelination and developing approaches aimed at promoting CNS remyelination, as they show little inflammation and, therefore, provide means to assay directly the effect of a therapy on remyelination. However, most of these models are developed in short-lived rodents and spontaneously repair, thus lacking the long-lasting progressive degenerative disease context of MS. Besides, these models do not reflect the size or complex organization of the human primate CNS (12). They do not inform on the biology of primate cells, which differs from rodents (13, 14), nor on the security, toxicity, and long-term efficacy of cell- or compound-based promyelinating/neuroprotective therapies. Thus, experiments in long-lived nonhuman primates appear an essential step toward clinical trials.While promoting remyelination may prevent axon degeneration, only a few promyelination strategies have been translated to the clinic (15,16). One of the roadblocks is the absence of studies addressing the clinical benefit of promyelination approaches that could be applied to the clinic (17). A positive correlation between changes in VEP parameters and the degree of demyelination/remyelination was established in rodents (18–21), cats (22), and dogs (23), and exploited successfully to follow promyelination therapies in rodents (24, 25). OCT has been used to identify loss of optic nerve and retinal damages in animal models of myelin disorders as well (23, 26). While used seldomly in nonhuman primates (27), none of these clinical assays were exploited to monitor the impact of optic nerve demyelination in nonhuman primates.We previously demonstrated that LPC injection in the macaque optic nerve induced demyelination with fair axon preservation but little remyelination up to 2 mo post demyelination (28). Taking advantage of the fact that nonhuman primates are long-lived and are able to perform several tasks awake, as do humans, we questioned whether this model could be used to follow the consequence of long-term demyelination on axon preservation, and whether multimodal noninvasive assays, such as VF, VEP, OCT, and PLR could be instrumental to follow/predict the functional and anatomical outcome of optic nerve demyelination. Using multidisciplinary approaches, we provide compelling evidence that LPC-induced demyelination of the macaque optic nerve leads to modified VF, VEP, PLR, and altered inner retinal layers, but preserved photoreceptors based on OCT and ERG. These clinical and functional anomalies were correlated at the histological level with failed remyelination and progressive optic nerve axon loss, followed by neuronal and fiber loss of the inner retinal layers. The postmortem validation of OCT, VEP, and PLR as pertinent markers of optic nerve demyelination/degeneration could further help the translation of therapeutic strategies toward the clinic for myelin diseases associated with long-term demyelination of the optic nerve.     

HPTN 068: A Randomized Control Trial of a Conditional Cash Transfer to Reduce HIV Infection in Young Women in South Africa—Study Design and Baseline Results

Young women in South Africa are at high risk for HIV infection. Cash transfers offer promise to reduce HIV risk. We present the design and baseline results from HPTN 068, a phase III, individually randomized trial to assess the effect of a conditional cash transfer on HIV acquisition among South African young women. A total of 2533 young women were randomized to receive a monthly cash transfer conditional on school attendance or to a control group. A number of individual-, partner-, household- and school-level factors were associated with HIV and HSV-2 infection. After adjusting for age, all levels were associated with an increased odds of HIV infection with partner-level factors conveying the strongest association (aOR 3.05 95 % CI 1.84–5.06). Interventions like cash transfers that address structural factors such as schooling and poverty have the potential to reduce HIV risk in young women in South Africa.     

Exposure of bakery and pastry apprentices to airborne flour dust using PM<Subscript>2.5</Subscript> and PM<Subscript>10</Subscript>personal samplers

Background  

This study describes exposure levels of bakery and pastry apprentices to flour dust, a known risk factor of occupational asthma.     

Antianaerobic activity of moxifloxacin compared with that of ofloxacin,ciprofloxacin, clindamycin,metronidazole and beta-lactams

Minimal inhibitory concentrations of moxifloxacin were compared with those of ofloxacin, ciprofloxacin, clindamycin, metronidazole and six beta-lactams for 159 anaerobes isolated from human clinical samples. Unlike other fluoroquinolones, moxifloxacin demonstrated high activity against the 76 strains of the Bacteroides fragilis group as the minimal inhibitory concentration(50) was 0.5 mg/l. Porphyromonas, Prevotella, Fusobacterium and Gram-positive anaerobic cocci were inhibited by 1 mg/l or less of moxifloxacin. It inhibited 93.7, 94.9 and 98% of the 159 strains investigated at concentrations of 1, 2 and 4 mg/l, respectively. Moxifloxacin was more potent than ofloxacin and ciprofloxacin against Gram-positive rods and anaerobic cocci. Its broad anaerobic spectrum in vitro is promising for the treatment of intra-abdominal and respiratory infections.     

Long-term pregabalin treatment protects basal cortices and delays the occurrence of spontaneous seizures in the lithium-pilocarpine model in the rat

PURPOSE: To determine whether a pharmacologic treatment could delay or prevent the epileptogenesis induced by status epilepticus (SE) through the protection of some brain areas, we studied the effects of the long-term exposure to pregabalin (PGB) on neuronal damage and epileptogenesis induced by lithium-pilocarpine SE. METHODS: SE was induced in adult and 21-day-old (P21) rats. At 20 min after pilocarpine, rats received 50 mg/kg PGB (pilo-preg) or saline (pilo-saline). PGB treatment was given daily at the dose of 50 mg/kg for 7 days after SE and at 10 mg/kg from day 8 until killing. Neuronal damage was assessed in hippocampus and piriform and entorhinal cortices in brain sections stained with thionine and obtained from adult and P21 animals killed 6 days after SE. The number of glial fibrillary acidic protein (GFAP)-reactive astrocytes was tested by immunohistochemistry in sections adjacent to those used for cell counting. The latency to spontaneous seizures was controlled by visual observation and EEG recording. RESULTS: PGB induced neuroprotection in layer II of piriform cortex and layers III-IV of ventral entorhinal cortex of adult rats, whereas no hippocampal region was protected. In P21 rats, damage was limited to the hilus and similar in pilo-preg and pilo-saline animals. The number of GFAP-positive astrocytes was higher in pilocarpine- than in saline-treated rats. It was decreased in pilo-preg compared with pilo-saline rats in layer II of the piriform cortex. Adult pilo-preg rats became epileptic after a longer latency (39 days) than did pilo-saline rats (22 days). CONCLUSIONS: These data underline the antiepileptogenic consequences of long-term PGB treatment, possibly mediated by the protection of piriform and entorhinal cortices in the lithium-pilocarpine model of epilepsy.